Technological Trends in CFD Applications

Authors

  • Genizia Islabão de Islabão IME - Instituto Militar de Engenharia
  • José Carlos Costa da Silva Pinto UFRJ - Universidade Federal do Rio de Janeiro
  • Ardson dos Santos Vianna Júnior IME - Instituto Militar de Engenharia

DOI:

https://doi.org/10.4067/S0718-27242010000200007

Keywords:

CFD, technology monitoring

Abstract

This article discusses a survey on the technology of Computational Fluid Dynamics (CFD) in various areas of knowledge and applied particularly in polymers, with scientific articles and patents as sources of information. All the data were mined using “computational”, “fluid” and “dynamic” as keywords. It was observed that private companies are responsible for regulatory filings and universities, research centers and institutes hold patents related to CFD. Moreover, most of the papers selected have authors affiliated with universities and research institutes. From the found papers, 25% are related to polymers, surpassing the percentage of 10% found in the analysis of patents.

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Author Biographies

Genizia Islabão de Islabão, IME - Instituto Militar de Engenharia

Departamento de Química

José Carlos Costa da Silva Pinto, UFRJ - Universidade Federal do Rio de Janeiro

Departamento de Engenharia Química

Ardson dos Santos Vianna Júnior, IME - Instituto Militar de Engenharia

Departamento de Química

References

ARIS, R. (1994). Mathematical Modelling Techniques. Dover, New York.

COURANT, R., Friedrichs, K.O., Lewy, H. (1928). Uuber die partiellen Differenzen-gleichungen der Math. Physik, Math Ann, 100, pp. 32-74.

DIXON, A.G., Taskina, M.E., Stittb, E.H., Nijemeislandb, M. (2007). 3D CFD simulations of steam reforming with resolved intraparticle reaction and gradients. Chemical Engineering Science, 62, pp. 4963- 4966.

INPI (2009). Instituto Nacional de Propriedade Industrial. http://www.inpi.gov.br [Accessed Noveber 18, 2009]

MILEWSKA, A., Molga, E.J. (2007). CFD simulation of accidents in industrial batch stirred tank reactors. Chemical Engineering Science, 62, 4920-4925.

RICHARDSON, L.F (1910). The approximate arithmetical solution by finite differences of physical problems involving differential equations, with an application to the stresses in a masonry dam. Phil Trans R Soc London, Series A; 210, 307-57.

SCOPUS (2009). Scopus. http://www.scopus.com [Accessed October 10, 2009]

SHANG, J.S. (2004). Three decades of accomplishments in computational fluid dynamics. Progress in Aerospace Sciences, 40, pp. 173-197.

SOUTHWELL, R.V. (1940). Relaxation methods in engineering science. Oxford University Press, London, UK.

VAKILI, M.H., Esfahany, M.N. (2009). CFD analysis of turbulence in a baffled stirred tank, a three-compartmentmodel. Chemical Engineering Science, 64, pp. 351-362.

VON NEUMANN, J, Richtmeyer, R.D. (1950). A method for the numerical calculation on the hydrodynamic shocks. J Appl Phys, 21, pp. 232-7.

LAX, P.D. (1954). Weak solution of nonlinear hyperbolic equations and their numerical computation. Commun Pure Appl Math, 7, pp. 159-63.

GODUNOV, S.K. (1959). Finite-difference method for numerical computational of discontinuous solution of the equations of fluid dynamics. Mat Sb, 47, pp. 271-306.

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Published

2010-08-16

How to Cite

Islabão, G. I. de, Pinto, J. C. C. da S., & Vianna Júnior, A. dos S. (2010). Technological Trends in CFD Applications. Journal of Technology Management & Innovation, 5(2), 76–83. https://doi.org/10.4067/S0718-27242010000200007

Issue

Section

Research Articles

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